欧洲赤松树脂道上皮细胞树脂分泌方式研究(英)

利用高压冷冻和冷冻替代技术对欧洲赤松（PinussylvestrisCarr．）茎皮层成熟树脂道上皮细胞的超微结构进行研究,揭示出一种全新的树脂分泌方式。其分泌过程为：一些含有水解酶的高尔基小泡,转移至质膜周围并释放水解酶,从而将质膜溶解形成分泌通道,树脂由此迅速转移至质膜外,然后,通过高尔基小泡相互融合形成新膜片段的方式来修补破损的质膜。     

Intracellular Transport and Elimination of Resin from Epithelial Duct-cells of Pinus halepensis

The ultrastructure of the resin secreting cells of root ductsof young Pinus halepensis seedlings was studied. It is suggestedthat the endoplasmic reticulum (ER) in addition to taking partin resin synthesis also plays a role in transporting the resinfrom the plastids, mitochondria and nuclear envelope to theplasmalemma. By fusing with the plasmalemma the ER releasesthe resin to the outside of the protoplast. The resin producedin the ground cytoplasm and by the Golgi apparatus seems tobe eliminated by plasmalemma invaginations. Pinus halepensis, resin secretion, root ducts, endoplasmic reticulum     

Ultrastructure of the Resin Ducts of Mangifera indica L. (Anacardiaceae). 3. Secretion of the Protein-polysaccharide Mucilage in the Fruit

Mango fruit ducts secrete a protein-carbohydrate mucilage inaddition to lipophilic material. This mucilage is secreted inspecial duct regions. Loops of ER elements seem to delimit cytoplasmicportions rich in ribosomes forming pseudo-vacuoles which eventuallybecome bound by a single membrane of ER origin. It is suggestedthat the protein is produced and accumulates in the pseudo-vacuoleswhich become storage bodies. Carbohydrates are added to thecontent of these bodies by Golgi vesicles. The cytoplasm becomesosmiophilic and contracts before disintegration, and the mucilagepasses into the space between plasmalemma and cell wall. Afterthe cell breaks down the mucilage is released into the ductcavity. Mangifera indica L., mango, Anacardiaceae, resin ducts, secretion, mucilage, ultrastructure     

油松含树脂细胞组织化学和细胞化学研究

油松茎端的皮层薄壁组织和幼茎木薄壁组织中具含树脂细胞分布,在光学显微镜下观察,硫酸奈尔兰染色的切片,发现树脂滴分布于细胞质中,在电子显微镜下观察狐染色切片,发现树脂滴分布于细胞的线粒体,高尔基体,内质网,核膜和小液泡中,同时也分布于质膜两边。从形态演化分析含树脂细胞在树脂分泌结构中属原始类型,由它演化为树脂道。     

Ultrastructure of the Resin Ducts of Mangifera indica L. (Anacardiaceae). 2. Resin Secretion in the Primary Stem Ducts

The resin of the mango stem consists mainly of terpenes. Theterpenes seem to be produced primarily by plastids, termed heresecretoplasts. At the beginning of the process of secretion,osmiophilic droplets are seen at the envelope of the secretoplastsand at elemints of periplastidal ER. In addition, such dropletsoccur also at Golgi bodies and occasionally in association withmitochondria. Later osmiophilic material fills the well-developbdER, which at this stage is mainly tubular. It appears that theER is involved in the transport of the sareted material towardsthe plasmalemma. Mangifera indica L., mango, Anacardiaceae, resin, resin ducts, secretion, secretoplasts, ultrastructure     

Ultrastructure of Resin Ducts in Pinus halepensis Development, Possible Sites of Resin Synthesis, and Mode of its Elimination from the Protoplast

Development of the resin duct cavity, sites of resin synthesisin the epithelial cells and elimination of resin from the protoplastwere studied in roots of young Pinus halepensis seedlings. Itis suggested that the Golgi bodies are involved in dissolutionof the middle lamella in the region of the future duct cavityby secretion of lytic enzymes into the cell walls. In earlystages of duct development osmiophilic droplets were observedin plastids, periplastidal and cytoplasmic ER, Golgi vesicles,mitochondria, nuclear envelope and in the cytoplasm. In thelatter they were often observed to be surrounded by a membrane.Electron micrographs suggested that elimination of resin dropletsfrom the protoplast occurs by their becoming surrounded by plasmalemmainvaginations.     

Origin of the Golgi system in amoebae

Summary An electron microscopic study of the Golgi apparatus in the giant amoeba, Pelomyxa illinoisensis, has been presented. Studies of normally feeding, dividing, starving, and refeeding amoebae were made. The major finding is that plasmalemma vesicles, formed via pinocytosis and phagocytosis, either flatten or invaginate and form the cisternae of the Golgi apparatus. Plasmalemma vesicles are also a source of new cisternae during the lifetime of a given Golgi apparatus. The cisternae migrate through the Golgi system, but before being released they either inflate, or segment into smaller vesicles. It is postulated that they later empty into the contractile vacuole and into certain other vacuoles. No evidence was found for the fusion of smooth Golgi vesicles or fringed vesicles of any kind with the plasmalemma.Dedicated to Professor Friedrich Wassermann with admiration and affection on the occasion of his eightieth birthday.Work supported by U. S. Atomic Energy Commission. A part of the work was reported at the XVI International Congress of Zoology, Washington, D. C., in 1963.     

Ultrastructural Study of Secondary Wall Formation in the Stem Fiber of Phyllostachys pubescens

Ultrastructural changes in secondary wall formation of Phyllostachys pubescens Mazel fiber were investigated with transmission electron microscopy. Fiber developed initially with the elongation of cells containing ribosomes, mitochondria and Golgi bodies in the dense cytoplasm. During the wall thickening, the number of rough endoplasmic reticulum and Golgi bodies increased apparently. There were two kinds of Golgi vesicles, together with the ones from endoplasmic reticulum formed transport vesicles. Many microtubules were arranged parallel to the long axis of the cell adjacent to the plasmalemma. Along with the further development of fiber, polylamellate structure of the secondary wall appeared, with concurrent agglutination of chromatin in the nucleus, swelling and disintegration of organelles, while cortical microtubules were still arranged neatly against the inner side of plasmalemma. Lomasomes could be observed between the wall and plasmalemma. The results indicated that the organelles, such as Golgi bodies together with small vesicles, rough endoplasmic reticulum and lomasomes, played the key role in the thickening and lignification of the secondary wall of bamboo fiber, though cortical microtubules were correlative with the process as well.     

毛竹茎纤维次生壁形成过程的超微结构观察

利用透射电镜观察了毛竹（Ｐｈｙｌｌｏｓｔａｃｈｙｓ ｐｕｂｅｓｃｅｎｓ Ｍａｚｅｌ）茎纤维发育过程中次生壁的形成过程。纤维发育早期,细胞具有较大的细胞核和核仁;细胞质浓稠,具有核糖体、线粒体和高尔基体等细胞器。随着纤维次生壁的形成,细胞壁加厚,细胞质变得稀薄,内质网和高尔基体的数量明显增加,并且两者共同参与了运输小泡的形成;在质膜内侧可观察到大量周质微管分布。随着次生壁的进一步加厚及木质化,细胞壁     

Golgi-mediated vicilin accumulation in pea cotyledon cells is re-directed by monensin and nigericin

Summary A range of drugs was applied to developing pea seed cotyledons in an attempt to perturb the intracellular transport of newly synthesized vicilin through the endoplasmic reticulum and Golgi vesicles to its site of storage, the vacuole. The most pronounced effects, produced by the ionophores monensin and nigericin, were on Golgi-mediated transport. Unlike the situation in most other tissues that have been studied the number of Golgi vesicles did not increase, suggesting that their movement is not slowed or stopped. However, the Golgi-mediated transport of vicilin was redirected from the vacuole tonoplast to the plasmalemma and the newly synthesized vicilin was released from the cotyledon cells to accumulate between the plasmalemma and the cell wall.     

OBSERVATIONS ON THE STRUCTURE OF SOME FORMS OF GOMPHONEMA PARVULUM KÜTZ. III. FRUSTULE FORMATION1

Gomphonema parvulum Kütz. was investigated by electron microscopy for details of frustule formation. An expansion of the cell along the pervalvar plane occurs prior to cell division. After nuclear division the organelles are, separated into 2 entities, either by division or by dispersion. The cell divides into 2 halves by the invagination of the plasmalemma which is derived from Golgi vesicular activity. When cytoplasmic cleavage, is complete, the Golgi actively produces electronlucent vesicles which collect and coalesce beneath the. plasmalemma to form the silicalemma around the silicon deposition vesicle. The endoplasmic reticulum is also closely associated with this vesicular activity. The vesicle gradually expands and becomes extremely electron dense as silica is deposited within it—first in the region, followed by the mantle edge. When the valve is mature, Golgi vesicles collect and fuse to form the silicalemma of the first girdle band. The first girdle band becomes aligned against the mantle edge on completion, by the “sloughing off” of the external silicalemma and plasmalemma. The second and third bands are formed, individually in a similar manner. Separation of the 2 daughter cells commences at the apical pole and progresses to the basal pole. The plasmalemma and external silicalemma are “sloughed off” so that the 2 cells can separate. The inner segment of the silicalemma becomes the new plasmalemma of the daughter cell.     

Structural differentiation of membranes involved in the secretion of polysaccharide slime by root cap cells of cress (Lepidium sativum L.)

The peripheral secretion tissue of the root cap of Lepidium sativum L. was investigated by electronmicroscopy and freeze-fracturing in order to study structural changes of membranes involved in the secretion process of polysaccharide slime. Exocytosis of slime-transporting vesicles occurs chiefly in the distal region of the anticlinal cell walls. The protoplasmic fracture face (PF) of the plasmalemma of this region is characterized by a high number of homogenously distributed intramembranous particles (IMPs) interrupted by areas nearly free of IMPs. Near such areas slime-transporting vesicles are found to be underlying the plasma membrane. It can be concluded that areas poor in particles are prospective sites for membrane fusion. During the formation of slime-transporting vesicles, the number of IMPs undergoes a striking change in the PF of dictyosome membranes and their derivatives. It is high in dictyosome cisternae and remarkably lower in the budding region at the periphery of the cisternae. Slime-transporting vesicles are as poor in IMPs as the areas of the plasmalemma. Microvesicles rich in IMPs are observed in the surroundings of dictyosomes. The results indicate that in the plasmalemma and in membranes of the Golgi apparatus special classes of proteins — recognizable as IMPs — are displaced laterally into adjacent membrane regions. Since the exoplasmic fracture face (EF) of these membranes is principally poor in particles, it can be concluded that membrane fusion occurs in areas characterized by a high quantity of lipid molecules. It is obvious that the Golgi apparatus regulates the molecular composition of the plasma membrane by selection of specific membrane components. The drastic membrane transformation during the formation of slime-transporting vesicles in the Golgi apparatus causes the enrichment of dictyosome membranes by IMPs, whereas the plasma membrane probably is enriched by lipids. The structural differentiations in both the plasma membrane and in Golgi membranes are discussed in relation to membrane transformation, membrane flow, membrane fusion, and recycling of membrane constituents.Abbreviations PF protoplasmic fracture face - EF exoplasmic fracture face - IMP intramembranous particle     

On the ultrastructure of differentiating secondary xylem in willow

Summary Studies of differentiating xylem inSalix fragilis L. show the immediate cambial derivatives to be ultrastructurally similar. The Golgi apparatus is important at all stages of wall synthesis, possibly producing (amongst other substances) hemicellulose material which is carried to the wall in vesicles or multivesicular bodies. The endoplasmic reticulum also contributes one or more components to the developing wall: at some stages during differentiation the endoplasmic reticulum produces electron opaque bodies which appear to be guided towards the wall by microtubules. Compact structures formed from concentric membranes (myelin-like bodies) have been found joined to rough endoplasmic reticulum, but their presence is not explained.Two types of plasmalemma elaboration occur: invagination of the plasmalemma itself to form vesicles which may contain cytoplasmic material; and vesicles between the plasmalemma and cell wall which are the result of single vesicles or multivesicular bodies traversing the plasmalemma. Both systems provide a means for transporting cytoplasmic material across the plasmalemma.Microtubules have been seen associated with all vesicles derived from the cytoplasm which appear to be moving towards the wall. The presence of microtubules may generally be explained in terms of orientation of vesicles, even if they also happen coincidentally to parallel the supposed orientation of microfibrils in the wall itself. It is possible to resolve connections between the microtubules and the plasmalemma.     

A histochemical study of variations in the localization of 5′-nucleotidase activity in the acinar cell of the rat exocrine pancreas over the twenty-four hour period

The circadian variation of 5'-nucleotidase (AMPase) activity was studied in rat pancreatic exocrine cells. The localization of this enzyme, often associated with the plasmalemma, was studied by ultracytochemical methods at six time points over the 24-h period. The localization of AMPase activity exhibited a clear-cut circadian variation. During the light span strong activity was observed on the luminal plasmalemma, negative or weak activity on the baso-lateral plasmalemma and clearly visible activity on intracellular structures such as cytoplasmic vacuoles (fragmentation-like vesicles), dilated rims of the Golgi cisternae (or cisternal ends of the Golgi stacks), condensing vacuoles and lysosomal bodies. During the dark span the activity was detectable only on the baso-lateral plasmalemma. The fact that AMPase activity could not be found on the luminal plasmalemma during the dark span suggests that the luminal membranes may be replaced by the membranes of secretory granules, which do not display AMPase activity. The intracellular localization of AMPase activity during the light span, especially at 08.00 h, includes all cytoplasmic compartments which have hitherto been associated with the intracellular pathway for membrane retrieval from the plasmalemma. Moreover, the appearance of the activity in the dilated rims of the Golgi stack and condensing vacuoles indicates that these compartments may constitute a functional unit.     

Immunocytochemical Evidence for Golgi Vesicle Involvement in Milk Fat Globule Secretion

The exact mechanism of secretion of the milk fat globule (MFG) from the mammary secretory cell is still controversial. We have previously suggested close involvement of Golgi vesicles in this process. This paper provides direct immunocytochemical evidence that butyrophilin is present in the Golgi stack and vesicles in ovine and caprine mammary glands. We suggest that it is the butyrophilin in the Golgi vesicle membrane that forms the specific association with the adipophilin on the lipid surface in the cytoplasm. Exocytosis of the associated Golgi vesicle will then initiate the process of MFG secretion. Further exocytosis of associated Golgi vesicles will continue and complete the process. Areas of the plasmalemma that have butyrophilin delivered by previous non-lipid associated Golgi exocytoses may also contribute to the process of forming the milk fat globule membrane (MFGM).     

The development and ultrastructure of gum ducts inCitrus plants formed as a result of brown-rot gummosis

Summary Young stems ofCitrus plants were infected with the fungusPhytophthora citrophthora. The effect of the infection on gum duct development was studied. The following sequence of structural changes was observed in the cambial zone: 1. The middle lamellae between layers of xylem mother cells dissolve forming duct cavities. 2. The cells around the duct cavities differentiate into epithelial cells rich in cytoplasm. 3. The amount of Golgi bodies and associated vesicles increases. The vesicles and small vacuoles, some of which seem to originate from the fusion of Golgi vesicles, contain fibrillar material that stains for polysaccharides. Vesicles and vacuoles appear to fuse with the plasmalemma. Material staining positively for polysaccharides accumulates between the plasmalemma and cell wall, and penetrates the latter. 4. The protoplast shrinks and the space below the cell wall, which contains polysaccharides, increases in volume. 5. After a period of 10 days or more the gum ducts become embedded in the xylem, and the activity of the epithelial cells ceases. The cell walls of many of them break, and the gum still present in the cells is released.     

Possible mechanism of the reorganization of the cardiomyocyte plasma membrane in the suslik in the hibernation-arousal-wakefulness cycle

Studies have been made on the ultrastructure of cardiomyocytes during hibernation and arousal of the ground squirrel C. undulatus. It was found that the number of elements of the rough endoplasmic reticulum, Golgi complex, vesicles and ribosomes increases in the perinuclear areas of cardiomyocytes during arousal of animals. These areas are saturated with lipid inclusions and mitochondria. Numerous vesicles and fringed bubbles were found near the plasma membrane which has many caveolae. These findings may indicate the intense metabolism of the membrane material between plasmalemma and cytoplasmic vesicles. Possible mode of rapid reorganization of the sarcolemma and changes in its functional properties during hibernation-arousal stages are suggested. It is concluded that apart from structural and functional properties which are acquired by cells during preparation of animals to hibernation and which exhibit only small changes during the whole period of hibernation, cyclic changes in plasmalemma structure and function occur during arousal of the ground squirrels.     

Wall and membrane biogenesis in the unusual labyrinthulid-like organismSorodiplophrys stercorea

Summary Electron microscopic investigations show the scale subunits of the walls ofSorodiplophrys stercorea to be produced by the Golgi apparatus. Their chief monosaccharide subunit is identified tentatively as arabinose. Membrane flow involving the nuclear envelope, endoplasmic reticulum, Golgi apparatus, Golgi vesicles, plasmalemma, and possibly prominent refractive bodies composed of membranes is suggested. Cytochemical data supporting ultrastructural evidence concerning the sites of scale and membrane biogenesis are presented.     

Association of Rab3A with synaptic vesicles at late stages of the secretory pathway

Rab3A is a small GTP-binding protein highly concentrated on synaptic vesicles. Like other small GTP-binding proteins it is thought to cycle between a soluble and a membrane-associated state. To determine at which stage of the life cycle of synaptic vesicles rab3A is associated with their membranes, the localization of the protein in neurons and neuroendocrine cells at different developmental and functional stages was investigated. In all cases, rab3A was colocalized with synaptic vesicle markers at the cell periphery, but was absent from the Golgi area, suggesting that rab3A associates with vesicles distally to the Golgi complex and dissociates from vesicle membranes before they recycle to this region. Immunofluorescence experiments carried out on frog motor end plates demonstrated that massive exocytosis of synaptic vesicles is accompanied by a translocation of rab3A to the cell surface. The selective localization of rab3A on synaptic vesicles at stages preceding their fusion with the plasmalemma suggests that the protein is part of a regulatory machinery that is assembled onto the vesicles in preparation for exocytosis.     

ULTRASTRUCTURE OF ZOIDOGENESIS IN UNILOCULAR ZOIDOCYSTS OF SEVERAL BROWN ALGAE1

Several different stages of the development of unilocular zoidocysts of small brown algae—Elachista fucicola, Hecatonema streblonematoides, Pylaiella littoralis—are observed by electron microscopy. 1. A slow growing phase is seen, during which nuclei and pheoplasts become associated by pairs and divide together, vacuoles and physodes are excreted through the plasmalemma, and Golgi bodies liberate vesicles with fibrillar material identical to the growing cell wall fibers. Mitochondria and Golgi bodies are concentrated under the very sinuous plasmalemma. 2. A very short spatial reorganization phase follows, during which organelles disperse between the nuclei-pheoplast pairs, cleavage vesicles appear, and flagella start developing. New pyrenoids form de novo. 3. The latter phase is followed by a longer maturation phase. Cleavage vesicles fuse and separate zoids grow as flagella. Mastigonemes formed in the endoplasmic reticulum are finally found in vesicles of a special Golgi body at the base of the anterior flagellum. They are liberated in parallel rows at the base of the already developed flagella by these Golgi's vesicles, and attach, on the flagella by an unknown process. Excretion of a mucilaginous substance takes place as the stigmas form de novo. 4. The ripe, swollen zoidocysts burst open, liberating the whole gelatinous mass. Naked zoids swim and settle on a substrate, retracting their flagella before excreting a new cell wall.